(511e) Layered and Scrolled Nanocomposites with Aligned Semi-Infinite Graphene Inclusions at the Platelet Limit

Authors: 
Liu, P., Massachusetts Institute of Technology
Jin, Z., Massachusetts Institute of Technology
Katsukis, G., Massachusetts Institute of Technology
Drahushuk, L., Massachusetts Institute of Technology
Shimizu, S., Massachusetts Institute of Technology
Shih, C. J., Massachusetts Institute of Technology
Wetzel, E. D., U.S. Army Research Laboratory
Taggart-Scarff, J., U.S. Army Research Laboratory
Qing, B., Massachusetts Institute of Technology
Li, R., Massachusetts Institute of Technology
Wardle, B., MIT
Strano, M., Massachusetts Institute of Technology
Graphene and other two-dimensional (2D) materials are distinct among nanoscale inclusions or fillers for composites in that they can potentially span the physical dimensions of the enclosing solid. However, alignment and assembly of continuous 2D components at high volume fraction and macroscopic dimensions remains an unsolved challenge in material science. Herein, we introduce a stacking and folding method that generates layer numbers that scale as 4j where j is the number of successive quadrant segmentations of a 2D inclusion, to generate aligned graphene/polycarbonate composites with as many as 320 parallel layers spanning 0.032 to 0.11 mm thickness. An analogous transverse shear scrolling method generates Archimedean spiral nanocomposite fibers 0.10-0.16 mm in diameter and 2 cm in length. The process significantly increases the effective elastic modulus approximately 1.9-fold to nearly 1 GPa, approaching the limit of platelet filler theory, and increases the ultimate tensile strength to 40 MPa even at exceptionally low graphene volume fraction of only 0.00185. Graphene spiral fibers demonstrate exotic, telescoping elongation at break of 110%, or 30 times greater than Kevlar. Both composite types retain anisotropic electrical conduction along the graphene planar axis with a percolation threshold VG < 0.003 vol%, and layer numbers less than 36 remain transparent with optical density < 42%. These results highlight new combinations of material properties available at this extreme platelet filler limit for nanocomposites.
Topics: